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Journal of Clinical Microbiology, April 1999, p. 1035-1044, Vol. 37, No. 4
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Development and Characterization of Complex DNA
Fingerprinting Probes for the Infectious Yeast Candida
dubliniensis
Sophie
Joly,
Claude
Pujol,
Michal
Rysz,
Kaaren
Vargas, and
David R.
Soll*
Department of Biological Sciences, University
of Iowa, Iowa City, Iowa 52242
Received 9 November 1998/Returned for modification 30 November
1998/Accepted 17 December 1998
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ABSTRACT |
Using a strategy to clone large genomic sequences containing
repetitive elements from the infectious yeast Candida
dubliniensis, the three unrelated sequences Cd1, Cd24, and Cd25,
with respective molecular sizes of 15,500, 10,000, and 16,000 bp, were
cloned and analyzed for their efficacy as DNA fingerprinting probes. Each generated a complex Southern blot hybridization pattern with endonuclease-digested genomic DNA. Cd1 generated an extremely variable
pattern that contained all of the bands of the pattern generated by the
repeat element RPS of Candida albicans. We demonstrated that Cd1 does not contain RPS but does contain a repeat element associated with RPS throughout the C. dubliniensis genome.
The Cd1 pattern was the least stable over time both in vitro and in vivo and for that reason proved most effective in assessing
microevolution. Cd24, which did not exhibit microevolution in vitro,
was highly variable in vivo, suggesting in vivo-dependent
microevolution. Cd25 was deemed the best probe for broad
epidemiological studies, since it was the most stable over time, was
the only truly C. dubliniensis-specific probe of the three,
generated the most complex pattern, was distributed throughout all
C. dubliniensis chromosomes, and separated a worldwide
collection of 57 C. dubliniensis isolates into two distinct
groups. The presence of a species-specific repetitive element in Cd25
adds weight to the already substantial evidence that C. dubliniensis represents a bona fide species.
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INTRODUCTION |
Candida albicans is the
most common yeast species carried as a commensal by healthy individuals
(42) and the most common species isolated from yeast
infections (21, 44). The next most common species include
Candida tropicalis, Candida glabrata, Candida parapsilosis, and Candida krusei (9,
25). All of these species are readily distinguishable from
C. albicans both phenotypically and genotypically. However,
over the years there have been an ever-increasing number of reports of
atypical strains of C. albicans that have been distinguished
primarily by unusual fingerprint patterns (3, 18, 19, 22, 27,
45). Based upon phenotypic and genotypic differences, Coleman,
Sullivan, and coworkers in Dublin, Ireland, were the first to argue
that a majority of these atypical C. albicans isolates
represented a separate species, which they named Candida
dubliniensis (46).
Because strains of the putative species C. dubliniensis
exhibited the two major phenotypic characteristics used to identify C. albicans, chlamydospore and true hypha formation
(46), and because they hybridized with putative C. albicans-specific fingerprinting probes (3, 22, 45,
46), there has been some hesitation in considering them members
of a bona fide species separate from C. albicans. However,
the fact that several DNA typing methods, including species-specific
probes (3, 22, 45, 46), multilocus enzyme electrophoresis
(3, 12, 27, 47), randomly amplified polymorphic DNA
(45, 46), electrophoretic karyotyping (46), oligonucleotide fingerprinting probes (45, 46),
microsatellite DNA analysis (20), and restriction fragment
length polymorphism without probes (46), discriminated these
strains from typical C. albicans strains suggested that they
indeed represent a separate species. For this reason, several methods
based on phenotype have recently been developed to distinguish isolates
of C. dubliniensis from isolates of C. albicans,
including growth at 42°C (7, 33, 46, 47), 
-glucosidase
activity (3, 33, 47), colony color on CHROMagar (7,
33), and fluorescence after growth on methyl blue-Sabouraud agar
(33). However, none of these methods appear to definitively
identify all C. dubliniensis isolates.
If C. dubliniensis is a bona fide species, it should contain
species-specific repetitive elements dispersed throughout the genome,
as has been demonstrated for C. albicans (28, 31, 40), C. tropicalis (11, 41), C. glabrata (15), C. krusei (4) and
C. parapsilosis (7a).
Demonstration of such species-specific sequences in the C. dubliniensis genome would not only reinforce the arguments by
Sullivan and Coleman (48) that it is a bona fide species but
also provide the basis for a DNA fingerprinting system (39).
We therefore screened for and cloned three DNA fingerprinting probes
that included moderately repetitive elements. One of them, Cd25, not
only proved to be effective in broad epidemiological studies but also
contained one or more C. dubliniensis-specific sequences
dispersed throughout the genome, supporting the argument that C. dubliniensis is a distinct species.
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MATERIALS AND METHODS |
Strains and growth conditions.
The C. dubliniensis strains used in this study are listed in Table
1. Each isolate was stored at room
temperature on a YPD agar slant (2% glucose, 2% Bacto Peptone, 1%
yeast extract, 2% agar) in a capped tube. For DNA extraction, the
cells were transferred to an Erlenmeyer flask containing YPD medium,
grown for 24 h at 25°C, and harvested. To assess the stability
of Southern blot hybridization patterns over many generations, cells
from a single clone were inoculated into YPD medium at an initial
concentration of 5 × 104 per ml and grown to
stationary phase (~24 h at 37°C). Stationary-phase cells were
diluted in fresh medium, and the process was repeated. After 200 generations, the cells were harvested and plated on agar at low density
and cells from nine colonies of each strain were removed and stored on
YPD slants in capped tubes for further analysis.
Cloning of genomic fragments containing moderately repetitive
sequences.
Genomic DNA from C. dubliniensis d1558
(Table 1) was used to construct a 
phage genomic library as
previously described for C. albicans (16, 28, 31, 40,
41). Briefly, the library was constructed in phage EMBL3
according to established protocols (29) with 9- to 23-kb
fragments from a Sau3AI partial digest of genomic DNA size
fractionated in a sucrose gradient (16). The library was
amplified in Escherichia coli P2-392 and plated at a density
of 10,000 plaques per 150-mm-diameter petri dish. Duplicate
nitrocellulose filters were prepared from each plate (29)
and incubated at 65°C for 20 min in a solution containing 1% bovine
serum albumin, 7% sodium dodecyl sulfate (SDS), 0.5 M
NaH2PO4 (pH 7.0), and 1 mM EDTA (6).
One filter of each set (filter A) was hybridized overnight with a total
of 106 cpm of random primer-labeled
[32P]dCTP-Sau3AI-TaqI-digested
genomic DNA of C. dubliniensis per ml. The second filter
(filter B) was hybridized overnight with 106 cpm of random
primer-labeled [32P]dCTP-ribosomal DNA of C. albicans per ml (43). The filters were washed first
with a solution containing 5% SDS, 40 mM
NaH2PO4, and 1 mM EDTA for 20 min and then with
a solution containing 1% SDS, 40 mM NaH2PO4,
and 1 mM EDTA for 20 min. The final filters were autoradiographed.
Filter A was compared to filter B to eliminate plaques that contained
ribosomal inserts. Clones that exhibited the more intense levels of
hybridization expected of repeat sequences (16) and that did
not hybridize to the ribosomal probe in filter B were selected,
rescreened under the same conditions, and plaque purified
(29). Since all clones selected as putative DNA
fingerprinting probes in the first screen generated similar
hybridization patterns with EcoRI-digested DNA from the same
test strains of C. dubliniensis, they were deemed to
represent the same family of repeats. To obtain additional unrelated
clones from the library, a second screen was conducted under less
stringent conditions. In the second screen, a representative sequence
that had been selected in the first screen, Cd1, was used to probe a
duplicate filter to exclude homologous clones. For the second screen,
Cd1 was subcloned into the pGEM-3Zf(+) plasmid vector. Prehybridization
(7 h at 65°C) and hybridization (overnight at 65°C) of the filters
were conducted in a solution of 50 mM NaH2PO4
(pH 7.5), 50 mM EDTA, 0.9 M NaCl, 5% dextran sulfate, 150 µg of
sheared denatured salmon sperm DNA per ml, and 0.3% SDS. The filters
were washed at 45°C with a solution containing 0.3 M NaCl, 0.03 M
sodium citrate (pH 7.0), and 0.2% SDS. In the second screen, clones
hybridizing to Cd1 or ribosomal DNA were excluded.
Southern blot hybridization and computer-assisted analysis.
Southern blot hybridization was performed as previously described
(11, 15, 16, 30, 32, 34, 40). Three µg of genomic DNA from
each isolate was digested with EcoRI (4 U/µg of DNA) for
16 h at 37°C. The digested DNA was electrophoresed overnight at
45 V in a 0.65% agarose gel for Cd1 and a 0.8% agarose gel for the
other clones. DNA was transferred to a nylon membrane by capillary
blotting (17). Digested DNA of reference strain M6 (Table 1)
was run in the far-right lane of each gel to facilitate computer-assisted analysis. The membrane was hybridized with a randomly
primed 32P-labeled probe and autoradiographed as previously
described (16, 32). Southern blots were then stripped of the
initial radiolabeled probe by incubating them first in a solution of
0.4 M sodium hydroxide for 30 min at 45°C and then in a solution of
0.015 M NaCl, 0.0015 M sodium citrate, 0.2 M Tris-HCl (pH 7.5), and
0.1% (wt/vol) SDS for 15 min at room temperature.
To analyze gel patterns, the autoradiograms were digitized into the
data file of the DENDRON software program version 2.0
(Solltech, Iowa
City, Iowa) with a Scanjet IIcx flatbed scanner
(Hewlett-Packard, Palo
Alto, Calif.). Distortions in the gels
were removed with the unwarping
option of DENDRON, and the lanes
and bands were automatically
identified. Southern blot hybridization
patterns were compared through
a similarity coefficient (
SAB)
based on band
position alone for every pair of patterns (isolates)
according to the
formula
SAB = 2
E/(2
E +
a +
b), where
E is the
number of bands shared by strains A
and B,
a is the number of
bands unique to A, and
b is the number of bands unique to B. An
SAB of 1.00 represented identical patterns, an
SAB of 0.0 represented
patterns with no
correlate bands, and
SABs ranging from 0.01 to
0.99 represented patterns with increasing proportions of bands
at the
same positions. Dendrograms based on
SAB values
were automatically
generated by the DENDRON program based on the
unweighted-pair
group method (
35).
CHEF electrophoresis.
Chromosomes were separated by
contour-clamped homogeneous electric field (CHEF) electrophoresis. To
generate spheroplasts, strains of C. dubliniensis and strain
3153A of C. albicans were grown overnight in YPD medium at
25°C. The cells were pelleted by centrifugation and washed twice with
sterile water and once with 1 M sorbitol. The cells were then incubated
for 30 min at room temperature in a solution containing 1 M sorbitol,
25 mM EDTA, and 50 mM dithiothreitol, harvested, washed with 1 M
sorbitol, and resuspended at a concentration of 109 per ml
in a solution containing 1 M sorbitol, 0.1 M sodium citrate (pH 5.8),
10 mM EDTA, and 0.4 mg of Zymolyase 100T (Seikagaku America, Rockville,
Md.)/ml at 37°C for 30 min. The cells were then pelleted, washed
twice with a solution containing 1 M sorbitol and 250 mM EDTA, and
resuspended in that solution at a final density of 109 per
ml. Agarose plugs were made by mixing in equal proportions the
suspension of spheroplasts and a solution of 1% agarose (Low Melt
Preparative Grade; Bio-Rad Laboratories, Hercules, Calif.) containing
10 mM Tris-HCl (pH 8.0) and 0.1 M EDTA. This mixture was poured into
plug molds for the CHEF mapper (Bio-Rad Laboratories). The plugs were
incubated in a solution containing 0.5 M EDTA, 1% Sarkosyl, and 5 mg
of proteinase K/ml for 72 h at 37°C, washed five times with a
solution containing 10 mM Tris-HCl (pH 8.0) and 1 mM EDTA, and finally
stored at 4°C. The plugs were loaded into wells of a 1% (wt/vol)
agarose gel containing 22.5 mM Tris-HCl (pH 8.3), 22.5 mM boric acid,
and 1 mM EDTA. The electrophoretic conditions providing the best
separation of chromosomes were a multistate protocol run at 14°C at
an angle of 120° and at a gradient of 4.5 V/cm. The pulse intervals
were 120 s for the first 24 h and 240 s for the final
36 h. Following electrophoresis, the gel was stained with ethidium
bromide, photographed, Southern blotted, and incubated with a
particular DNA probe (29).
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RESULTS |
Cloning putative DNA fingerprinting probes.
A library was
constructed in EMBL3 from a Sau3AI partial digest of
genomic DNA from C. dubliniensis d1558 (Table 1). Digestion products ranged between 9 and 23 kb. The library was plated on five
dishes, generating approximately 10,000 plaques per dish. The library
on each plate was transferred to duplicate nitrocellulose filters and
hybridized in parallel with either radiolabeled C. dubliniensis genomic DNA or a radiolabeled ribosomal DNA probe of
C. albicans. Under nonsaturating conditions, clones
containing repeat sequences generated stronger signals than
clones containing unique sequences. This difference was the basis of
the screen (8, 11, 15, 16, 28, 31, 38). Twenty clones which hybridized intensively with genomic DNA, but not with the ribosomal probe, were selected for further analysis. The screen was repeated to
verify that each clone contained a nonribosomal repeat sequence. The 20 clones were plaque purified, labeled, and used to probe Southern blots
of EcoRI-digested DNA of three unrelated test strains of
C. dubliniensis to assess the effectiveness of the clones as fingerprinting probes. Of the original 20 clones tested, 19 (95%) generated complex Southern blot hybridization patterns that varied among the three test strains. However, all of the 19 clones generated similar patterns for a particular strain, suggesting that the clones
contained one or more common sequences. To assess the relatedness of
the 19 clones, each was digested with SalI and
EcoRI, electrophoresed in a 0.8% (wt/vol) agarose gel for
4 h, and stained with ethidium bromide. Seventeen different
digestion patterns were generated, which suggested that 17 of the 19 related clones originated from different genomic sites or represented
partial overlaps at the same sites. One representative of this family,
Cd1, with an estimated size of 15,500 bp, was selected for further analysis.
To obtain additional, unrelated probes, a second screen was performed
under the same conditions as the first, except that
hybridization of
the nitrocellulose membranes was performed at
lower stringency. To
exclude sequences homologous to Cd1, the
Cd1 fragment was cloned into
the pGEM-3Zf(+) plasmid vector and
used to probe an additional filter
in the screen. Of approximately
100,000 plaques, 100 displayed a signal
of relatively high intensity
and did not hybridize with either
ribosomal DNA or the Cd1 plasmid.
Of these, 26 were selected and
analyzed. Fifteen generated complex
polymorphic patterns when used to
probe the three test strains
of
C. dubliniensis. Two general
patterns were generated by the
15 probes, suggesting that two
additional families of probes containing
repetitive sequences were
represented. One representative clone
from each family, Cd24 and Cd25,
were selected for further analysis.
The estimated sizes of Cd24 and
Cd25 were 10,000 and 16,000 bp,
respectively.
Genetic variability displayed by the three selected probes.
To
test the effectiveness of the three cloned probes and
cross-hybridization with C. albicans DNA, each clone was
used to probe Southern blots of nine unrelated test isolates of
C. dubliniensis and C. albicans 3153A (Fig.
1). The Cd1 probe generated between 9 and
15 bands ranging from 4.6 to 31 kb for each of the nine test strains
(Fig. 1A). Cd1 generated significantly different patterns for all nine
test strains, even the ones originating from patients treated in the
same hospital (e.g., d88029 and d90015, and M3 and M4) (Fig. 1A). Cd1
generated two monomorphic bands (i.e., bands at the same molecular
weight in the nine test strains) at 4.6 and 5.3 kb (Fig. 1A), as well
as several moderately variable bands and several highly variable bands.
In the dendrogram generated for Cd1 in Fig. 1A, the two pairs of
isolates with the highest SABs (0.77 in both
cases) were Co4 and M3, and Co5 and M4. The isolates in each pair were
from different countries. The Cd1 probe generated three bands with
EcoRI-digested DNA of C. albicans 3153A, a weak
one at 31 kb and a weak one and a moderately intense one below 4.6 kb
(Fig. 1A).
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FIG. 1.
Southern blot hybridization patterns and resulting
dendrograms of EcoRI-digested DNA of nine C. dubliniensis isolates and C. albicans 3153A probed with
Cd1(A), Cd24 (B), and Cd25 (C). The DNA was electrophoresed in a 0.65%
agarose gel, and the Southern blot was sequentially hybridized with the
three probes. The arrowheads to the right of each gel represent
prominent invariant (monomorphic) bands. Key molecular sizes are
presented in kilobases to the left of each gel. The origins of these
test isolates are presented in Table 1. A dendrogram (shown below each
gel) for each set of hybridization patterns was generated from the
similarity coefficient (SAB) computed for all
possible pairs of the nine unrelated C. dubliniensis
isolates. Since the M3 lane was underloaded, analyses of that pattern
were performed on autoradiograms exposed for longer periods. The
average SAB is indicated at the top of each
dendrogram.
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The Cd24 probe also generated significantly different patterns for all
nine test strains (Fig.
1B). Cd24 generated four monomorphic
bands, a
few moderately variable bands, and several highly variable
bands. In
the dendrogram generated for Cd24 (Fig.
1B), the pair
of isolates with
the highest
SAB (0.89) was P30 and Co4. The Cd24
probe generated five moderately intense bands and two very weak
bands
with DNA of
C. albicans 3153A (Fig.
1B).
The Cd25 probe also generated significantly different patterns for all
of the nine test strains (Fig.
1C). Cd25 generated
the most complex
pattern of the three tested probes. The patterns
contained 10 monomorphic bands as well as several moderately variable
bands and
several highly variable bands. In the dendrogram generated
for Cd25
(Fig.
1C), the pair of isolates with the highest
SAB (0.98) was P30 and Co4, the same pair
exhibiting the highest
SAB in the Cd24
dendrogram (Fig.
1B). Cd25 was the only probe of the
three with no
significant hybridization to DNA of
C. albicans 3153A (Fig.
1C).
The patterns generated by Cd1, Cd24, and Cd25 were distinctly
different. None of the monomorphic or highly variable bands
were
common, supporting the conclusion that the three probes were
unrelated.
The relationship of Cd1 and the C. albicans repetitive
element RPS.
Two of the three probes, Cd1 and Cd24, hybridized
with EcoRI-digested DNA of C. albicans 3153A
(Fig. 1A and B). Since the C. albicans fingerprinting probes
Ca3 (32) and 27A (31) have been demonstrated to
cross-hybridize with C. dubliniensis DNA (3, 46,
47), we tested whether any of the three C. dubliniensis probes identified the same genomic fragments as Ca3
and 27A. The gel shown in Fig. 1 was reprobed with the C1 fragment of
Ca3 (1, 14), which contains a portion of the C. albicans repetitive sequence RPS (13), with a cloned
RPS element, RPS39 (27a), and with the probe 27A
(31), which also contains an RPS element (27a).
RPS39 has 99% homology with other published RPS sequences (27a). The probes C1, RPS39, and 27A all generated the
same pattern for each of the nine C. dubliniensis test
strains (Fig. 2B, C, and D,
respectively). This pattern contained approximately 80% of the bands
present in the respective Cd1 patterns (Fig. 2A).
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FIG. 2.
Hybridization patterns of the nine test isolates of
C. dubliniensis and C. albicans 3153A probed with
the Cd1 probe (A), the C1 fragment of the C. albicans
probe Ca3 (B) (1), the RPS39 element of C. albicans (C) (27a), and the C. albicans
probe 27A (30). The origins of the test isolates are
presented in Table 1. Molecular sizes are presented in kilobases
to the left of each set of hybridization patterns.
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While probes C1, RPS39, and 27A generated patterns of four to eight
bands when hybridized to
EcoRI-digested
C. albicans DNA
(Fig.
2A, B, and C, respectively), Cd1 generated only
one moderately
intense band and two very weak bands (Fig.
2A), none of
which
corresponded to the bands generated by C1, RPS39, and 27A. These
results suggest that Cd1 contains a
C. dubliniensis-specific
sequence
dispersed throughout the
C. dubliniensis genome in
close association
with an RPS-like element but that the Cd1 probe
itself does not
contain an RPS
sequence.
Cross-verification of the probes Cd1, Cd24, and Cd25.
Since
the three C. dubliniensis probes represent unrelated genomic
fragments, they can be considered unrelated fingerprinting methods and
can, therefore, be used to cross-verify efficacy by cluster analysis
(11, 15, 26, 39, 49). Cd25 generated the most complex
Southern blot hybridization patterns and the highest average
SAB when used as a probe to fingerprint the nine test isolates (Fig. 1A). It grouped isolates P30 and Co4 into the most
related cluster, grouped M3 and M4 into a moderately related cluster,
and identified d1425638 and d90015 as the most unrelated isolates in
the collection. Cd24 also grouped isolates P30 and Co4 into the most
related cluster, grouped M3 and M4 into a moderately related cluster,
and identified d1425638 and d90015 as the most unrelated isolates in
the collection. This was not the case for Cd1. Cd1 did not group P30
and Co4 into the most related cluster, did not group M3 and M4 in a
moderately related cluster, and did not identify d1425638 and d90015 as
the most unrelated isolates. These results demonstrate that relative
parity exists between Cd25 and Cd24 as fingerprinting probes, but not between either of these probes and Cd1.
The distribution of sequences homologous to Cd1, Cd24, and Cd25 in
the C. dubliniensis genome.
Twelve chromosomal bands
and one minichromosomal band were separated by CHEF from C. dubliniensis M6, and eight chromosomal bands and one
minichromosomal band were separated from C. dubliniensis d126423 (Fig. 3A). Eight chromosomal
bands and one minichromosomal band were separated from C. albicans 3153A (Fig. 3A). Cd1 hybridized to all chromosomal and
minichromosomal bands of both C. dubliniensis strains (Fig.
3B). The degree of hybridization varied substantially among chromosomal
bands. Cd1 also hybridized to all C. albicans chromosomal
bands except band 3 (Fig. 1B). RPS39 also hybridized to all chromosomal
bands of the two C. dubliniensis strains except band 4 and
hybridized to all C. albicans chromosomal bands except band
three (Fig. 3E). Moreover, the relative differences between the Cd1
hybridization intensities of the C. dubliniensis bands (Fig.
3B) were the same when RPS39 was used as a probe (Fig. 3E). These
results demonstrate that Cd1 sequences are dispersed throughout the
C. dubliniensis genome and are associated in all or a
majority of cases with RPS sequences.
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FIG. 3.
Hybridization of CHEF-separated chromosomes of C. dubliniensis (C.d.) and C. albicans (C.a.) with the
C. dubliniensis probes Cd1, Cd24, and Cd25 and the C. albicans repeat element RPS39. Chromosomes of C. albicans 3153A and C. dubliniensis M6 and d126423 were
separated by CHEF, and the gel was stained with ethidium bromide (EtBr)
(A). The gels were then Southern blotted and probed with Cd1(B), Cd24
(C), Cd25 (D), and RPS39 (E). C. albicans bands are numbered
to the left of the EtBr-stained image, and C. dubliniensis
bands are numbered to the right of the EtBr-stained image. m,
minichromosomal band.
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Cd24, on the other hand, hybridized to only two chromosomal bands and
the minichromosomal band of
C. dubliniensis M6 and to
only
one chromosomal band and the minichromosomal band of
C. dubliniensis d126423 (Fig.
3C). Cd24 also hybridized to one
chromosomal band
of
C. albicans 3153A (Fig.
3C). Therefore,
although Cd24 generates
a complex Southern blot hybridization pattern
with
EcoRI-digested
C. dubliniensis DNA, it is
distributed on only one to two
chromosomes.
Cd25 hybridized to all chromosomal bands and the minichromosomal band
of the two
C. dubliniensis strains (Fig.
3D). Cd25,
therefore, is distributed on all
C. dubliniensis
chromosomes.
It hybridized to no
C. albicans chromosomal
bands (Fig.
3D), supporting
the conclusion that Cd25 is the only
C. dubliniensis-specific
probe of the three clones
analyzed.
Species specificity of Cd1, Cd24, and Cd25.
Each of the three
clones was used to probe Southern blots of EcoRI-digested
DNA of 14 related yeast species (Fig. 4).
Cd1 hybridized strongly with C. dubliniensis DNA, very
weakly with C. albicans DNA, and not at all with the DNA of
the remaining 12 species (Fig. 4A). Cd24 hybridized strongly with
C. dubliniensis DNA, weakly with C. albicans DNA,
and not at all with DNA of the remaining 12 species (Fig. 4B). Cd25
hybridized strongly with C. dubliniensis DNA but not at all
with DNA of the remaining 13 species (Fig. 4C). When the C. albicans repeat element RPS39 was used to probe the same blot, it
hybridized strongly with C. dubliniensis and C. albicans DNA, but not at all with DNA from the remaining 12 species (data not shown). These results demonstrate that Cd1 and Cd24
are C. dubliniensis and C. albicans specific, and
that Cd25 is C. dubliniensis specific.
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FIG. 4.
Species specificity of the three C. dubliniensis probes. EcoRI-digested DNA of 14 different
yeast species was sequentially probed with Cd1 (A), Cd24 (B), Cd25 (C),
and the C. albicans repeat element RPS39 (D). Lanes:
C.g., Candida guillermondii; C.r.,
Candida rugosa; C.kr., C. krusei;
C.l., Candida lusitaniae; C.gl.,
C. glabrata; P., Pichia sp.;
C.t., C. tropicalis; Y.l.,
Yarrowia lipolytica; S.c., Saccharomyces
cerevisiae; C.a., C. albicans;
T.b., Trichosporon beigelii; C.k.,
Candida kefyr; C.d., C. dubliniensis;
C.p., C. parapsilosis.
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Stability of the DNA fingerprint patterns generated by Cd1, Cd24,
and Cd25.
The stability of the patterns generated by the three
C. dubliniensis probes was first tested in vitro for three
unrelated strains grown from single colonies for 200 generations. Cells from each of the final growth cultures were plated on agar, and cells
from nine colonies of each strain as well as from each original clone
were analyzed by Southern blot hybridization with the probes Cd1, Cd24,
and Cd25. Stability proved to be both strain and probe related. The
nine clones of strain d1419-2 obtained after 200 generations exhibited
no differences from each other or from the original clone when
fingerprinted with any of the three probes (Fig.
5A). The nine clones of strain B71507
exhibited no differences from each other or from the original clone
with probes Cd24 or Cd25 but displayed two patterns with probe Cd1
(patterns 1 and 2), one of which (pattern 1) was the same as that of
the original clone (Fig. 5B). Pattern 1 differed from pattern 2 by an
8.8-kb band present in the latter but not in the former. The nine
clones of strain Co5 exhibited no differences from each other or from the original clone with probe Cd24. However, the nine clones displayed three patterns (patterns 1, 2, and 3) when probed with Cd25 (Fig. 5C).
One of the patterns (pattern 1) was the same as that of the original
clone (Fig. 5C). The nine clones of strain Co5 exhibited eight
different patterns (patterns 2 through 9) when probed with Cd1. All of
these patterns differed from that of the original clone (pattern 1 [Fig. 5C]). These results demonstrate that Cd24 provides the most
stable pattern, Cd25 provides the second most stable pattern, and Cd1
provides the least stable pattern over time in vitro. These results
also demonstrate that strain d1419-2 has the most stable genotype and
strain Co5 has the least stable genotype in vitro.
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FIG. 5.
In vitro analysis of the stability of the patterns
generated by C. dubliniensis probes Cd1, Cd24, and Cd25.
Southern blots of EcoRI-digested DNA from clones of C. dubliniensis d1419-2 (A), B71507 (B), and Co5 (C), at zero hours
(0) and after 200 generations, were probed with Cd1, Cd24, and Cd25.
Nine individual clones of each strain were selected randomly for
analysis at 200 generations. Variant patterns are numbered at the
bottom of each blot. Key molecular sizes in kilobases are presented to
the left of each blot.
|
|
To examine the patterns generated by the three probes in vivo, 15
C. dubliniensis isolates were recovered from the oral cavity
of a human immunodeficiency virus (HIV)-positive patient at the
University of Iowa Hospitals and Clinics over a 12-month period
(Table
1, patient 50). One isolate was obtained at time zero,
seven isolates
were obtained at 5 months, two isolates were obtained
at 7 months, and
five isolates were obtained at 12 months. The
last isolates, collected
at 12 months, were obtained when the
patient presented with his first
episode of oral thrush. All isolates
were analyzed by Southern blot
hybridization with probes Cd1 (Fig.
6A),
Cd24 (Fig.
6B), and Cd25 (Fig.
6C). All three probes separated
the
collection of 15 isolates into two groups distinguishable
by the
general fingerprint patterns. The first, group a, was composed
of 13 isolates, and the second, group b, was composed of 2 isolates.
The
separation into two groups is evident in the dendrograms generated
from
the hybridization patterns of each probe (Fig.
6). The node
separating
group a and b isolates occurred at
SABs of 0.39, 0.27,
and 0.75 for probes Cd1, Cd24, and Cd25, respectively (Fig.
6).
These node
SABs are all below the average
SAB for unrelated isolates
(Fig.
1). Probe Cd1
distinguished differences between the two
b isolates, but probes Cd24
and Cd25 did not (Fig.
6). It should
be noted that the time interval
between collection of the two
b isolates was 7 months (Fig.
6).
Variability was observed in
group a isolates with all three probes
(Fig.
6). However, the
least variability occurred in the Cd25 patterns.
For the 13 isolates
in group a, Cd1 distinguished 11 patterns, Cd24
distinguished
7 patterns, and Cd25 distinguished 3 patterns (Fig.
6,
see the
pattern analysis at the bottom of each gel). These results
demonstrate
that Cd25 provides the most stable pattern in vivo and in
vitro,
while Cd1 and Cd24, on the other hand, distinguish greater
variability
within a strain over time and are, therefore, superior for
assessing
microevolution.
View larger version (69K):
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[in a new window]
|
FIG. 6.
The variability of probe-generated patterns in a
population colonizing an HIV-positive individual over time.
EcoRI-digested DNA from multiple isolates from patient 50 (Table 1) were probed with Cd1 (A), Cd24 (B), and Cd25 (C). The
isolates were obtained at 0, 5, 7, and 12 months. The patient presented
with oral thrush at 12 months. Variations in patterns are indicated at
the bottom of each blot. This patient was infected by two different
strains displaying the general genotypes a and b. Changes in the
patterns are numbered in chronological order of occurrence. Molecular
sizes are presented in kilobases to the left of the gels. On the right
side of each hybridized Southern blot the representative dendrogram is
generated. The average SAB is presented at the
top of each dendrogram.
|
|
Analysis of a broad collection of C. dubliniensis
isolates with the probe Cd25.
Because Cd25 was deemed the best
probe for broad epidemiological studies, it was used to analyze the
relatedness of 57 independent C. dubliniensis isolates
collected in 11 countries (Table 1). Among the 57 isolates, Cd25
discriminated 53 different patterns (Fig.
7). Of the four pairs of identical
isolates, three pairs consisted of isolates collected from different
patients in the same hospitals, suggesting that each represented
nosocomial strains endemic to the respective hospitals (23,
24). Furthermore, of 31 isolates collected from eight hospitals
(Fig. 7, A through H), 67% grouped in clusters that contained only
strains from a single hospital, suggesting the presence of nosocomial
strains endemic to the respective hospitals. Only one pair of identical isolates in the entire collection, d952 and ANSA28 (Fig. 7), was derived from individuals in different hospitals and countries (Table
1).
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 7.
Dendrograms generated from the similarity coefficients
(SABs) computed for all pairs of 57 unrelated
isolates collected worldwide and fingerprinted with Cd25. The origins
of the isolates are presented in Table 1. The letters (A through H) to
the right of the dendrogram indicate the hospitals of origin in cases
where several isolates, each from a different individual, were
collected from the same hospital: A, Brussels, Belgium; B, Leicester,
United Kingdom; C, London, United Kingdom; D, Antwerp, Belgium; E,
Frankfurt, Germany; F, Victoria, Australia; G, Lausanne, Switzerland;
H, Leeds, United Kingdom. The two main clusters are delineated to the
right of the dendrogram (groups I and II). The average
SABs for each group, and for the total
collection, are presented in the middle of the dendrogram.
|
|
The isolates in this broad collection separated into two general
groups, group I and group II (Fig.
7). The two groups were
separated by
a node at an
SAB of 0.24 (Fig.
7). Group I,
which
contained 49 isolates, had an average
SAB
of 0.80. Group I isolates
shared several common, or monomorphic, bands
(Fig.
8). In contrast,
Group II, which
contained eight isolates, had a relatively low
average
SAB of 0.47 (Fig.
7). This low average
SAB suggests a
high level of diversity within
the group. The difference between
the two groups is evident in the
representative patterns in Fig.
8. While group I patterns were similar,
group II patterns differed
markedly not only from group I patterns but
also from each other.
Group II isolates lacked, for the most part, the
monomorphic bands
described in the original comparison of the three
probes (Fig.
1 and
5), which, by chance, was performed with only group
I isolates.
View larger version (72K):
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[in a new window]
|
FIG. 8.
Examples of Southern blot hybridization patterns of
group I and group II isolates probed with Cd25. Hybridization patterns
are presented in A, and a model generated by the DENDRON program is
presented in B. Molecular sizes are presented in kilobases to the left
of the hybridization pattern. The arrowheads to the right of the model
indicate the prominent invariant bands shared by group I isolates but
not by group II isolates.
|
|
Analysis of isolates from the same individuals with the probe
Cd25.
In the worldwide collection analyzed in this study, multiple
isolates were obtained from nine individuals. When these multiple isolates were added to the dendrogram in Fig. 7, in all cases but one
the isolates from the same individual clustered at an SAB of 0.95 to 1.00 (data not shown).
| |
DISCUSSION |
At the phenotypic level of analysis, a number of traits are
readily distinguishable between the majority of C. albicans
and C. dubliniensis isolates (48). Perhaps the
most definitive is the inability of C. dubliniensis isolates
to express -glucosidase (3, 33, 47). However, conclusive
differences must be assessed at the genetic level before one would feel
comfortable separating a set of atypical C. albicans
isolates with common phenotypes into a bona fide new species,
especially in view of the capacity of C. albicans and
related species to change their phenotypes in so pleiotropic a fashion
through reversible high-frequency phenotypic switching (36).
The first clues that genetic differences also existed between typical
and atypical C. albicans isolates came from reports that the
latter exhibited diminished hybridization patterns with the related
probes 27A (46, 47) and Ca3 (22) and that
atypical strains could be readily distinguished from other species,
including C. albicans, by restriction fragment length
polymorphisms generated from HinfI-digested DNA
(46), randomly amplified polymorphic DNA analysis
(46), hybridization to oligonucleotides homologous to
microsatellites (45, 46), PCR products of primers homologous
to CARE-2 (18, 19), electrophoretic karyotypes (2,
46), multilocus enzyme electrophoresis (3, 12, 27,
47), and sequencing ribosomal DNA (46).
C. dubliniensis-specific repeat elements support its
status as a species.
We have cloned and characterized complex DNA
fingerprinting probes from C. albicans (28, 40),
C. glabrata (15), C. tropicalis (11), and Aspergillus fumigatus (8)
and have found in all cases that they contain repetitive,
species-specific sequences. We hypothesized that the repetitive
sequences harbored by these probes have evolved rapidly enough to be
species specific and, therefore, to be good indicators of speciation.
Here, we have cloned one complex probe, Cd25, that is homologous to
sequences dispersed throughout the C. dubliniensis genome
and produces no detectable signal when used to probe 13 related yeast
species, including C. albicans. The evolution of this
specific sequence in a subgroup of atypical C. albicans
strains with common phenotypic traits supports the argument by Coleman
and Sullivan (48) that C. dubliniensis represents
a bona fide species. However, by the same argument, we have presented
contradictory evidence that this subgroup of atypical C. albicans isolates also contains dispersed homologs of the C. albicans-specific RPS repetitive element (5, 10). These
apparently contradictory results are accommodated by a relatively
straightforward explanation. C. albicans and C. dubliniensis both may have evolved from a common ancestor that possessed RPS elements. After separation, C. dubliniensis
acquired the repeat element in Cd25 that is dispersed throughout its
genome. Therefore, C. albicans and C. dubliniensis are closely enough related to share a repetitive
element (RPS) not found in any other Candida species but
distant enough not to share the repetitive element in Cd25.
The potential of Cd1, Cd24, and Cd25 as C. dubliniensis
DNA fingerprinting probes.
Although all three probes generated
complex Southern blot hybridization patterns, they were not equal in
their capacities to discriminate among isolates. Cd1 produced far more
variable patterns between moderately related and unrelated isolates and did not achieve parity with the other two probes in a cluster analysis
of nine test isolates. The pattern generated by Cd1 was also far less
stable both in vitro and in vivo than those generated by the other two
probes. Because of its decreased stability, Cd1 is less effective in
clustering moderately related isolates and therefore will not perform
well in broad epidemiological studies. On the other hand, Cd1 is
superior to both Cd24 and Cd25 in discriminating microevolutionary
changes in clonal populations. These characteristics are similar to
those noted for the C. albicans probe 27A and the C1
fragment of Ca3, both of which are composed predominately of RPS
sequences (27a). Curiously, Cd24 did not discriminate
microevolution in the three clones grown for 200 generations in vitro
but was an excellent indicator of microevolution in one clonal
population of C. dubliniensis monitored over a 12-month
period in an HIV-positive patient. These results suggest either that
the infecting strain in the HIV-positive patient had gone through far
more than 200 generations or that variations in the Cd24 pattern are
induced by in vivo conditions.
Although Cd24 and Cd25 achieved parity in the cluster analysis, Cd24
generated the least complex pattern of the three probes
and exhibited
the highest level of hybridization with
C. albicans DNA.
Cd24 was also the least dispersed sequence in the
C. dubliniensis genome. Cd25, therefore, was selected as the probe of
choice for
broad epidemiological studies. It generated the most stable
pattern
over time for clonal populations in vitro and in vivo, produced
the most complex pattern, produced the pattern with the greatest
number
of monomorphic bands for group I isolates, and produced
the pattern
with the most highly resolved bands of the three probes.
Cd25 was also
the only
C. dubliniensis-specific probe. However,
as noted,
Cd25 was the least effective of the three probes in
discriminating
microevolution within an infecting
strain.
Analysis of a broad collection of C. dubliniensis
isolates.
In an analysis by Southern blot hybridization with the
Cd25 probe of 57 isolates collected in 11 countries, two groups were identified, group I and group II. Group I comprised 86% of all isolates and exhibited an average SAB of 0.80, which was relatively high given the complexity of the pattern generated
by Cd25. Group II comprised 14% of all isolates and exhibited an
average SAB of 0.47, which was relatively low.
The lower SAB suggests that the isolates in
group II are relatively unrelated. The greater degree of variability
among group II isolates suggests either that they have a higher
frequency of Cd25 sequence reorganization than group I isolates or that
group I represents a younger and therefore more homogeneous subgroup of
C. dubliniensis that has rapidly become predominant
worldwide. The very low node value that separates groups I and II
(SAB = 0.24) suggests reproductive isolation
between the two groups.
Of the eight group II isolates, six (75%) were collected in the United
Kingdom and the remaining two were collected in Spain
and the
Netherlands. Since the isolates from the United Kingdom
comprised only
30% of the test collection, it would appear that
group II isolates may
be disproportionately concentrated in the
United Kingdom. Further
analysis of a larger number of
C. dubliniensis isolates
obtained worldwide is now being performed to verify the
separation of
C. dubliniensis into groups I and II described
above.
| |
ACKNOWLEDGMENTS |
This work was supported by Public Health Service grants DE10758
and AI2392 from the National Institutes of Health.
We are indebted to F. Odds of Janssen Pharmaceutics; Patrick Boerlin of
the Institute of Microbiology at Lausanne, Switzerland; M. McCullough
of the School of Dental Science at Melbourne, Australia; and M. Pfaller
of the University of Iowa for many of the isolates used in this study.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dept. of
Biological Sciences, University of Iowa, Iowa City, IA 52242. Phone:
(319) 335-1117. Fax: (319) 335-2772. E-mail:
david-soll{at}uiowa.edu.
| |
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Journal of Clinical Microbiology, April 1999, p. 1035-1044, Vol. 37, No. 4
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
